Background Chronic kidney disease is associated with a marked increase in risk for left
ventricular hypertrophy and cardiovascular mortality compared with the general
population. Therapy with vitamin D receptor activators has been linked with reduced
mortality in chronic kidney disease and an improvement in left ventricular
hypertrophy in animal studies.
PurposePRIMO (Paricalcitol capsules benefits in
Renal failure Induced cardia
MOrbidity) is a multinational, multicenter randomized controlled
trial to assess the effects of paricalcitol (a selective vitamin D receptor
activator) on mild to moderate left ventricular hypertrophy in patients with chronic
kidney disease.
Methods Subjects with mild-moderate chronic kidney disease are randomized to
paricalcitol or placebo after confirming left ventricular hypertrophy using a cardiac
echocardiogram. Cardiac magnetic resonance imaging is then used to assess left
ventricular mass index at baseline, 24 and 48 weeks, which is the primary efficacy
endpoint of the study. Because of limited prior data to estimate sample size, a
maximum information group sequential design with sample size re-estimation is
implemented to allow sample size adjustment based on the nuisance parameter estimated
using the interim data. An interim efficacy analysis is planned at a pre-specified
time point conditioned on the status of enrollment. The decision to increase sample
size depends on the observed treatment effect. A repeated measures analysis model,
using available data at Week 24 and 48 with a backup model of an ANCOVA analyzing
change from baseline to the final nonmissing observation, are pre-specified to
evaluate the treatment effect. Gamma-family of spending function is employed to
control family-wise Type I error rate as stopping for success is planned in the
interim efficacy analysis.
Limitations If enrollment is slower than anticipated, the smaller sample size used in the
interim efficacy analysis and the greater percent of missing week 48 data might
decrease the parameter estimation accuracy, either for the nuisance parameter or for
the treatment effect, which might in turn affect the interim decision-making.
Conclusions The application of combining a group sequential design with a sample-size
re-estimation in clinical trial design has the potential to improve efficiency and to
increase the probability of trial success while ensuring integrity of the study.
Get full access to this article
View all access options for this article.
References
1.
CoreshJSelvinEStevensLA. Prevalence of chronic kidney disease in the United
States. Jama2007; 298:
2038–47.
2.
Department of Health and Human Services.
Disparities in premature deaths from heart disease–50 states and
the district of Columbia, 2001. MMWR Morb Mortal Wkly
Rep2004; 53:
121–25.
3.
LevyDGarrisonRJSavageDD. Prognostic implications of echocardiographically
determined left ventricular mass in the Framingham Heart Study.
N Engl J Med1990; 322:
1561–66.
4.
PfefferMABraunwaldEMoyeLA. Effect of captopril on mortality and morbidity in
patients with left ventricular dysfunction after myocardial infarction. Results of
the survival and ventricular enlargement trial. The SAVE
Investigators. N Engl J Med1992; 327:
669–77.
5.
DevereuxRBWachtellKGerdtsE. Prognostic significance of left ventricular mass
change during treatment of hypertension. Jama2004; 292:
2350–56.
6.
StewartGAGansevoortRTMarkPB. Electrocardiographic abnormalities and uremic
cardiomyopathy. Kidney Int2005; 67:
217–26.
7.
VermaAAnavekarNSMerisA. The relationship between renal function and cardiac
structure, function, and prognosis after myocardial infarction: the VALIANT Echo
Study. J Am Coll Cardiol2007; 50:
1238–45.
8.
TengMWolfMLowrieE. Survival of patients undergoing hemodialysis with
paricalcitol or calcitriol therapy. N Engl J Med2003; 349:
446–56.
9.
TengMWolfMOfsthunMN. Activated injectable vitamin D and hemodialysis
survival: a historical cohort study. J Am Soc
Nephrol2005; 16:
1115–25.
10.
Kalantar-ZadehKKuwaeNRegidorDL. Survival predictability of time-varying indicators of
bone disease in maintenance hemodialysis patients. Kidney
Int2006; 70:
771–80.
11.
ShobenABRudserKDde BoerIH. Association of oral calcitriol with improved survival
in nondialyzed CKD. J Am Soc Nephrol2008; 19:
1613–19.
12.
KovesdyCPAhmadzadehSAndersonJEKalantar-ZadehK. Association of activated vitamin D treatment and
mortality in chronic kidney disease. Arch Intern
Med2008; 168:
397–403.
13.
Naves-DiazMAlvarez-HernandezDPasslick-DeetjenJ. Oral active vitamin D is associated with improved
survival in hemodialysis patients. Kidney Int2008; 74:
1070–78.
14.
BodyakNAyusJCAchingerS. Activated vitamin D attenuates left ventricular
abnormalities induced by dietary sodium in Dahl salt-sensitive
animals. P Natl Acad Sci USA2007; 104:
16810–15.
15.
ThadhaniR. Targeted ablation of the vitamin D 1alpha-hydroxylase
gene: getting to the heart of the matter. Kidney
Int2008; 74:
141–43.
16.
WeishaarRESimpsonRU. Vitamin D3 and cardiovascular function in
rats. J Clin Invest1987; 79:
1706–12.
17.
SimpsonRUHersheySHNibbelinkKA. Characterization of heart size and blood pressure in
the vitamin D receptor knockout mouse. J Steroid Biochem
Mol Biol2007; 103:
521–24.
18.
XiangWKongJChenS. Cardiac hypertrophy in vitamin D receptor knockout
mice: role of the systemic and cardiac renin-angiotensin systems.
Am J Physiol Endocrinol Metab2005; 288:
E125–32.
19.
WuJGaramiMChengTGardnerDG. 1,25(OH)2 vitamin D3, and retinoic acid antagonize
endothelin-stimulated hypertrophy of neonatal rat cardiac
myocytes. J Clin Invest1996; 97:
1577–88.
20.
ThadhaniRAppelbaumEChangY. Vitamin D receptor activation and left ventricular
hypertrophy in advanced kidney disease. Am J
Nephrol2011; 33:
139–49.
21.
StewartGAFosterJCowanM. Echocardiography overestimates left ventricular mass
in hemodialysis patients relative to magnetic resonance imaging.
Kidney Int1999; 56:
2248–53.
22.
SaltonCJChuangMLO'DonnellCJ. Gender differences and normal left ventricular
anatomy in an adult population free of hypertension. A cardiovascular magnetic
resonance study of the Framingham Heart Study Offspring cohort.
J Am Coll Cardiol2002; 39:
1055–60.
23.
BellengerNGDaviesLCFrancisJM. Reduction in sample size for studies of remodeling in
heart failure by the use of cardiovascular magnetic resonance.
J Cardiovasc Magn Reson2000; 2:
271–78.
24.
BottiniPBCarrAAPrisantLM. Magnetic resonance imaging compared to
echocardiography to assess left ventricular mass in the hypertensive
patient. Am J Hypertens1995; 8:
221–28.
25.
CulletonBFWalshMKlarenbachSW. Effect of frequent nocturnal hemodialysis vs
conventional hemodialysis on left ventricular mass and quality of life: a
randomized controlled trial. Jama2007; 298:
1291–99.
26.
ChanCTFlorasJSMillerJA. Regression of left ventricular hypertrophy after
conversion to nocturnal hemodialysis. Kidney Int2002; 61:
2235–39.
27.
BauerPKohneK. Evaluation of experiments with adaptive interim
analyses. Biometrics1994; 50:
1029–41.
28.
LehmacherWWassmerG. Adaptive sample size calculations in group sequential
trials. Biometrics1999; 55:
1286–90.
29.
MullerHHSchaferH. Adaptive group sequential designs for clinical
trials: combining the advantages of adaptive and of classical group sequential
approaches. Biometrics2001; 57:
886–91.
30.
ChiLHungHMWangSJ. Modification of sample size in group sequential
clinical trials. Biometrics1999; 55:
853–57.
31.
BornkampBBretzFDmitrienkoA. Innovative approaches for designing and analyzing
adaptive dose-ranging trials. J Biopharm Stat2007; 17:
965–95.
32.
KramsMLeesKRHackeW. Acute Stroke Therapy by Inhibition of Neutrophils
(ASTIN): an adaptive dose-response study of UK-279,276 in acute ischemic
stroke. Stroke2003; 34:
2543–48.
33.
MussHBBerryDACirrincioneCT. Adjuvant chemotherapy in older women with early-stage
breast cancer. N Engl J Med2009; 360:
2055–65.
34.
MehtaCRPatelNR. Adaptive, group sequential and decision theoretic
approaches to sample size determination. Stat Med2006; 25: 3250–69;
discussion 3297–301, 3302–04, 3313–14, 3326–47.
35.
RitzELavilleMBilousRW. Target level for hemoglobin correction in patients
with diabetes and CKD: primary results of the Anemia Correction in Diabetes
(ACORD) Study. Am J Kidney Dis2007; 49:
194–207.
36.
LevinADjurdjevOThompsonC. Canadian randomized trial of hemoglobin maintenance
to prevent or delay left ventricular mass growth in patients with
CKD. Am J Kidney Dis2005; 46:
799–811.
37.
RogerSDMcMahonLPClarksonA. Effects of early and late intervention with epoetin
alpha on left ventricular mass among patients with chronic kidney disease (stage 3
or 4): results of a randomized clinical trial. J Am Soc
Nephrol2004; 15:
148–56.
38.
ParfreyPSFoleyRNWittreichBH. Double-blind comparison of full and partial anemia
correction in incident hemodialysis patients without symptomatic heart
disease. J Am Soc Nephrol2005; 16:
2180–89.
39.
PittBReichekNWillenbrockR. Effects of eplerenone, enalapril, and
eplerenone/enalapril in patients with essential hypertension and left ventricular
hypertrophy: the 4 E-left ventricular hypertrophy study.
Circulation2003; 108:
1831–38.
40.
SolomonSDAppelbaumEManningWJ. Effect of the direct Renin inhibitor aliskiren, the
Angiotensin receptor blocker losartan, or both on left ventricular mass in
patients with hypertension and left ventricular hypertrophy.
Circulation2009; 119:
530–37.
41.
ZoccaliCBenedettoFAMallamaciF. Prognostic impact of the indexation of left
ventricular mass in patients undergoing dialysis. J Am Soc
Nephrol2001; 12:
2768–74.
42.
MehtaCTsiatisAA. Flexible sample size consideration using
information-based interim monitoring. Drug Infor
J2001; 35:
1095–112.
43.
GouldALShihWJ. Sample size re-estimation without unblinding for
normally distributed outcomes with unknown variance. Com
Stat Theory Meth1992; 21:
2833–53.
44.
PocockSJ. Group sequential methods in the design and analysis
of clinical trials. Biometrika1977; 64:
191–99.
45.
O'BrienPCFlemingTR. A multiple testing procedure for clinical
trials. Biometrics1979; 35:
549–56.
